How #Blockchain Technology Can Reinvent The Power Grid

A power pole collapses at 8 p.m. on a hot night in the remote outback of Australia. This is a problem for William and Olivia Munroe, who raise sheep and cattle 100 miles outside an old gold mining town on the edge of the Great Victoria Desert. In the summer, the temperature frequently soars close to 120 degrees Fahrenheit. Their children attend school via satellite link, the family’s only means of accessing health services in case of illness or emergency. Although the Munroes have a backup generator, it can’t power the water pumps, communications, and air-conditioning for long. In short, their lives depend entirely upon reliable energy.

Nine hours later, the power utility sends out a team to find and fix the downed pole. Customer complaints give the company an idea of where the break occurred, but the team takes more than a day to identify, reach, and fix the pole. Meanwhile, the Munroes and nearby residents, businesses, and institutions go without power and connectivity at considerable inconvenience, economic impact, and physical risk. In the outback, blackouts are not just paralyzing; they’re dangerous. To minimize these hazards, at great expense the company deploys teams of inspectors to check the network regularly.

Imagine how much safer, easier, and cheaper it would be if each power pole were a smart thing. It could report its own status and trigger actions for replacement or repair. If a pole caught fire or began to tip or fall, it would generate an incident report in real time and notify a repair crew to come with the appropriate equipment to the precise location. Meanwhile, the pole could potentially reassign its responsibilities to the nearest working pole. After all, they’re all on the grid. The utility could restore power to the community more quickly without the huge ongoing costs of field inspection.

Using emerging software and technologies associated with the Internet of Things, we can instill intelligence into existing infrastructure such as a power grid by adding smart devices that can communicate with one another. Imagine creating a new flexible and secure network quickly and relatively inexpensively that enables more opportunities for new services, more participants, and greater economic value.

This configuration is known as a mesh network, that is, a network that connects computers and other devices directly to one another. They can automatically reconfigure themselves depending upon availability of bandwidth, storage, or other capacity and therefore resist breakage or other interruption. Communities can use mesh networks for basic connectivity where they lack access or affordable service. Mesh networks are alternatives to traditional top-down models of organization, regulation, and control; they can provide greater privacy and security because traffic doesn’t route through a central organization.

Organizations are already combining mesh networks with blockchain technology to solve complex infrastructure problems. Filament, an American company, is experimenting with what it calls “taps” on power poles in the Australian outback. These devices can talk directly to each other at distances of up to 10 miles. Because the power poles are approximately 200 feet apart, a motion detector on a pole that’s falling will notify the next pole 200 feet away that it’s in trouble. If for any reason the tap on that pole isn’t available, it will communicate with the next pole, or the next pole, for up to 10 miles, that will communicate to the company through the closest Internet backhaul location within 120 miles.

Customers can connect to the devices directly with their own phone, tablet, or computer. The tap can contain numerous sensors to detect temperature, humidity, light, and sound, all of which customers could use to monitor and analyze conditions over time. They could meter these data as an information service or license the data set through the blockchain to another user, such as a government, broadcaster, pole manufacturer, or environmental agency.

Filament’s business model is a service model involving three parties: Filament, its integration customer, and the utility company. Filament owns the hardware; its devices continually monitor the condition of the power poles and report changes. It sells the sensor data stream to the integrator, and this integrator sells to the utility.

The utility pays monthly for a monitoring service. The service enables the power company to eliminate the very expensive field inspection of its operations. Because power poles rarely fall, the power company rarely uses the actual communication capability of the mesh network